Dynamic jack reference control system and method for extending vehicle jacks

ABSTRACT

A dynamic jack reference control system may include a tilt sensor operatively associated with the vehicle so that the tilt sensor senses a tilt angle of the vehicle. A processor operatively connected to the tilt sensor produces a jack reference value based on the tilt angle of the vehicle. A speed controller operatively associated with the processor extends the at least one jack on the vehicle at a speed that is related to the jack reference value.

CROSS-REFERENCE TO RELATED APPLICATIONS

This invention is a continuation of pending U.S. patent application Ser.No. 12/616,380, filed on Nov. 11, 2009, and is hereby incorporatedherein by reference for all that it discloses.

FIELD OF THE INVENTION

This invention relates to vehicles having stabilizing jacks in generaland more specifically to methods and systems for extending the jacks.

BACKGROUND OF THE INVENTION

Numerous kinds of vehicles having retractable jacks for stabilizationand/or lifting are known in the art and are used in a wide range ofapplications. Typically, the stabilizing jacks are hydraulicallyoperated and are moveable between retracted and extended positions. Whenin the retracted position, the stabilizing jacks are out of the way andallow the vehicle to move about without interference from the jacks.When in the extended position, the stabilizing jacks contact the groundand support at least a portion, if not the entirety, of the vehicle. Incertain applications, the jacks may be used merely to stabilize thevehicle, whereas in other applications, the jacks my lift all or aportion of the vehicle to level the vehicle or otherwise position thevehicle in a desired attitude.

While such stabilizing jack systems may be manually controlled, manyjack systems are partially- or fully-automated, and use a jackdeployment system to automatically extend or deploy the jacks until theyprovide the desired degree of lift or stabilization. In such anapplication, the jack deployment system may utilize one or more tiltsensors to detect or sense the tilt angle or attitude of the vehicle.The jack deployment system extends the various vehicle jacks until thetilt sensors indicate that the vehicle has been leveled or has otherwisereached the desired attitude.

Unfortunately, however, such jack deployment systems are not withouttheir drawbacks. For example, one problem that can arise relates to thesensitivity of the tilt sensors used to sense the attitude or tilt angleof the vehicle. If the sensors are too sensitive compared with theability of the jack deployment system to position the vehicle within acertain tolerance, the system may have difficulty achieving the desiredtilt or attitude set point. The system may “hunt” excessively in anattempt to achieve the attitude set point. While this problem can beovercome by re-calibrating the tilt sensors (i.e., to change the scalingfactors); such re-calibration reduces the resolution of the sensors,thereby reducing the leveling accuracy of the system. Indeed, in systemsinvolving such re-calibrated sensors, it is not unusual for the actualleveling accuracy to be many times lower than the design accuracy. Forexample, a system designed to level within 0.1 degree may actually onlylevel to within 0.4 degree.

Another solution is to filter the output of the tilt sensor tosmooth-out the signal. Unfortunately, however, such filtering may causethe jack deployment system to over- or under-shoot the desired attitudeset point. If this occurs, the jack deployment system may repeatedlytilt the vehicle back and forth in an attempt to achieve the desiredattitude set point. Besides increasing the amount of time required forthe system to achieve the desired attitude, such back and forth vehiclemotion can impose excessive stress on the vehicle. Even worse, if thesystem is not properly damped, there is a danger that the back and forthmotion will cause the vehicle to enter a harmonic vibration state. Suchharmonic vibrations are of particular concern if the vehicle is providedlarge, mast-like structures, such as a drill derrick.

In addition to the structural problems caused by such repeated back andforth vehicle motion, such motion can result in excessive settling ofthe vehicle on the supporting ground, which can further increase thedifficulty in achieving the desired attitude set point. Indeed, in somecases the overall system hysteresis caused by jack settling can make itimpossible for the jack deployment system to ever achieve the desiredattitude set point.

Still other problems may stem from the particular speed at which thejacks are extended. For example, a fast jack extension speed increasesthe likelihood that the jack deployment system will overshoot thedesired set point. As described above, such overshooting of the desireset point may lead to excessive back and forth vehicle motion, increasedvehicle stress, the danger of inducing harmonic vibrations, and settlinghysteresis, all of which are deleterious. Moreover, fast jack extensionspeeds may require rapid cycling of the jack actuators as the vehiclenears the desired attitude set point. Such rapid cycling can imposeexcessive stresses on the jacks and may also induce harmonic vibrationsin the vehicle structure.

On the other hand, if the jack extension speed is too slow, the systemmay require an excessive period of time to achieve the desired attitudeset point, particularly if the initial vehicle attitude departssignificantly from the desired attitude set point. In addition,undershooting the desired set point may also result in undesirable backand forth vehicle motion as the jack extension system attempts to reachthe desired attitude set point.

BRIEF SUMMARY OF THE INVENTION

A system for extending at least one jack on a vehicle may include a tiltsensor operatively associated with the vehicle so that the tilt sensorsenses a tilt angle of the vehicle. A processor operatively connected tothe tilt sensor produces a jack reference value based on the tilt angleof the vehicle. A speed controller operatively associated with theprocessor extends the at least one jack on the vehicle at a speed thatis related to the jack reference value.

A method for extending at least one jack on a vehicle according to oneembodiment of the invention may include: Sensing a tilt angle of thevehicle; producing a jack reference value based on the sensed tiltangle; and extending the at least one jack at a speed that is related tothe jack reference value.

Also disclosed is a method for leveling a jacked vehicle that involves:(a) sensing a pitch angle of the vehicle; (b) sensing a roll angle ofthe vehicle; (c) producing a pitch reference value that is related tothe sensed pitch angle of the vehicle; (d) producing a roll referencevalue that is related to the sensed roll angle of the vehicle; (e)extending a vehicle jack that affects at least the pitch angle of thevehicle at a speed that is related to the pitch reference value; (f)extending a vehicle jack that affects at least the roll angle of thevehicle at a speed that is related to the roll reference value; and (g)repeating (a)-(f) until the sum of the pitch and roll angles falls belowa predetermined angle.

BRIEF DESCRIPTION OF THE DRAWINGS

Illustrative and presently preferred exemplary embodiments of theinvention are shown in the drawings in which:

FIG. 1 is a side view in elevation of a drill rig embodying the dynamicjack reference control system of the present invention;

FIG. 2 is a drill end view in elevation of the drill rig illustrated inFIG. 1;

FIG. 3 is a functional block diagram of one embodiment of the dynamicjack reference control system;

FIG. 4 is a flow chart of a method for dynamically determining a jackreference value according to one embodiment of the present invention;

FIG. 5 is a flow chart of one embodiment of a method for producing ajack reference value;

FIG. 6 is a graphical depiction of a jack reference value that is alinear function of sensed tilt angle;

FIG. 7 is a graphical depiction of a jack reference value that is anexponential function of sensed tilt angle;

FIG. 8 is a flow chart of another embodiment of a method for producing ajack reference value from a look-up table; and

FIG. 9 is a graphical depiction of a relationship between jack referencevalues and sensed tilt angles defined in one embodiment of a look-uptable.

DETAILED DESCRIPTION OF THE INVENTION

A dynamic jack reference control system 10 according to one embodimentof the present invention is shown and described herein as it may beutilized on a on a drill rig 12 of the type commonly used in mining andquarrying operations to drill blastholes (not shown). Alternatively, thesystem 10 may be used in any of a wide range of other applications andother vehicle types, as would become apparent to persons having ordinaryskill in the art after having become familiar with the teachingsprovided herein. Consequently, the present invention should not beregarded as limited to the particular vehicle (e.g., drill rig 12) andapplication (e.g., blasthole drilling) shown and described herein.

Referring now primarily to FIGS. 1-3, drill rig 12 may be provided witha plurality of jacks 14 that may be operated or controlled by a jackdeployment system 16. In the embodiment shown and described herein, jackdeployment system 16 may comprise an automated or semi-automated jackdeployment system that may be operated to extend the various jacks 14 ondrill rig 12 until the drill rig 12 has reached the desired set point orattitude, typically a level attitude. The dynamic jack reference controlsystem 10 controls or varies the speeds at which the various jacks 14are extended or retracted based on the tilt angle of the vehicle. Statedanother way, while the jack deployment system 16 extends or retracts thevarious jacks 14 to achieve the desired vehicle attitude, the dynamicjack reference control system 10 controls the speed at which the variousjacks 14 are extended or retracted. The dynamic jack reference controlsystem 10 varies the extension (or retraction) speed of the jacks 14until the drill rig 12 has achieved the desired attitude.

Referring now primarily to FIG. 3, the dynamic jack reference controlsystem 10 may comprise a processor system 18 that is operativelyassociated a speed controller 20. Speed controller may also beoperatively associated with the jack deployment system 16 and thevarious jacks 14 so that speed controller 20 can control the speed atwhich the various jack or jacks 14 are extended or retracted. The system10 may also comprise at one or more tilt sensors, such as a pitch sensor22 and a roll sensor 24, that are operatively connected to the processor18. Pitch sensor 22 senses a pitch attitude or angle 26 (FIG. 1) ofdrill rig 12 and produces a pitch output signal 28 that is related tothe pitch angle 26. Similarly, roll sensor 24 senses a roll attitude orangle 30 (FIG. 2) of drill rig 12 and produces a roll output signal 32that is related to the roll angle 30. Processor 18 uses the pitch androll output signals 28 and 32 to determine the speed at which the jacks14 are to be extended.

In the particular embodiment shown and described herein, the pitch androll sensors 22 and 24 are also connected to the jack deployment system16. Jack deployment system 16 uses the pitch and roll output signals 28and 32 to determine when the drill rig 12 has achieved the desired tiltangle or set point attitude.

With reference now primarily to FIG. 4, the dynamic jack referencecontrol system 10 may be programmed or configured to implement a method34 for extending or retracting the various jacks 14 on the vehicle,e.g., drill rig 12. A first step 36 in method 34 involves sensing thetilt angle (e.g., the pitch angle 26 and/or roll angle 30) of the drillrig 12. At the start of the jack extension process, the tilt angle willbe the initial or starting tilt angle of the drill rig 12. Thereafter,as the jacks 14 are extending, the sensed tilt angle will be theinstantaneous tilt angle (i.e., the tilt angle of the drill rig 12 atthat particular point in time). After sensing the tilt angle, method 34then proceeds to step 38 to determine whether the desired tilt angle hasbeen achieved. If so, jack extension operation is terminated or stoppedat step 40. If not, the method 34 proceeds to step 42 which involves theproduction of a jack reference value. As used herein, a jack referencevalue refers to the percentage of the maximum available jack extension(or retraction) speed for the particular jack or jacks 14 involved. Forexample, a jack reference value of 100% means that the jacks 14 will beallowed to extend at the maximum available rate for the particular jackor jacks 14 being extended. Similarly, a jack reference value of 50%means that the jack or jacks 14 will be allowed to extend at half themaximum available rate for the particular jack or jacks 14 that arebeing extended.

In the present invention, the jack reference value 42 is based on thesensed tilt angle, or more precisely the difference between the sensedtilt angle and the desired set point value or angle. In one embodiment,the jack reference value produced by step 42 is proportional to thesensed tilt angle. Thus, higher tilt angles (i.e., the differencebetween the sensed tilt angle and the desired set point value) willresult in higher jack reference values, whereas lower tilt angles willresult in lower jack reference values.

Still further, and depending on the particular embodiment, the jackreference value may be selected to be a certain defined function of thesensed tilt angle. For example, in one embodiment, the jack referencevalue may be linear function of the sensed tilt angle, as depicted inFIG. 6. In another embodiment, the jack reference value may be anexponential function of the sensed tilt angle, as illustrated in FIG. 7.In still yet another alternative, the jack reference value may bedetermined or produced by reference to a look-up table (LUT) 44 providedin a memory system 46 associated with processor 18. See FIG. 3. In oneembodiment, the look-up table (LUT) 44 may define jack reference valuethat is a step function of the sensed tilt angle, as depicted in FIG. 9.Alternatively, other functions or relations may be defined by the LUT44.

Regardless of the particular function or relation that may be utilizedto determine the jack reference value from the sensed tilt angle, oncethe jack reference value has been determined at step 42, method 34proceeds to step 48 wherein the jack reference value is applied to speedcontroller 20. Then, at step 50, speed controller 20 uses the jackreference value to adjust or vary the extension speeds of the jacks 14.For example, if the jack reference value produced in step 42 is 100%,then speed controller 20 will allow the jacks 14 to be extended at themaximum available speed. That is, when commanded by the jack deploymentsystem 16 to extend one or more of the jacks 14, the speed controller 20will control the extension speed of the particular jack or jacks 14involved. Similarly, a jack reference value of 50% applied to the speedcontroller 20 will cause the speed controller 20 (i.e., in response tocommands from the jack deployment system 16) to control the extensionspeed of the jacks 14 to half the maximum available jack extensionspeed.

The various steps of method 34 will continue to be repeated until thedesired tilt angle has been achieved, as determined by step 38. That is,the system 10 will continue to sense the tilt angle (at step 36),produce a jack reference value based on the sensed tilt angle (at step42), apply the newly produced reference value to the speed controller 20(at step 48) and extend the jacks 14 (at step 50), until the drill rig12 has achieved the desired tilt angle or attitude. Thereafter, the jackextension process may be terminated, at step 40.

The system 10 may be operated in accordance with method 34 to control orvary the speed at which the various jacks 14 are extended by the jackdeployment system 16. Significantly, and as will be described in muchgreater detail herein, the speed at which the jacks 14 are extended isrelated to the sensed tilt angle of the drill rig 14. If the initialsensed tilt angle exceeds the desired tilt angle by a significant amount(for example, if the vehicle is far out of level), the system 10 willproduce a jack reference value that will allow the jacks 14 to beextended at the maximum available extension speed. Then, as the sensedtilt angle approaches the desired tilt angle (for example, as thevehicle approaches the desired attitude), the jack reference valueproduced in step 42 will decrease, with a minimum jack extension speedbeing used when the sensed tilt angle of the vehicle is close to thedesired attitude. The minimum extension speed may continue to be useduntil the drill rig 12 has reached the desired attitude or tilt angle(or falls within a specified tolerance of the desired tilt angle). Atthat point, the jack deployment system 16 may terminate the jackextension process.

A significant advantage of the present invention is that it allows thejacks to be extended to achieve a desired vehicle attitude without theproblems associated with prior art systems. For example, the rapid jackextension afforded by the present invention when the tilt angle of thevehicle departs significantly from the desired tilt angle allows thevehicle to more rapidly approach the desired attitude. However, when thedesired attitude is approached, the reduced jack extension speedsignificantly reduces the likelihood that the vehicle will overshoot thedesired attitude. The system also avoids the problems associated withexcessive back and forth motion of the vehicle during the levelingprocess, which can create excessive stress in vehicle components, andcreate leveling problems due to soil or ground settling. The system alsoavoids the need to rapidly cycle or operate the jack actuators as thevehicle approaches the desired attitude. In addition, the presentinvention also does not suffer from the loss of leveling accuracytypically associated with systems that rely on re-calibration of thesensors. Still yet another advantage of the present invention is that itmay be used to control both the extension and retraction speeds of thejacks.

Having briefly described one embodiment of a dynamic jack referencecontrol system 10 as well as a method 34 for extending the vehiclejacks, various embodiments and variations of the systems and methods ofthe present invention will now be described in detail. However, beforeproceeding with the detailed description, it should be noted that whilethe systems and methods are shown and described herein as they could beimplemented on a blasthole drill rig 12 of the type commonly used inmining and quarrying operations, they could be used on other vehicletypes and in other applications, as would become apparent to personshaving ordinary skill in the art after having become familiar with theteachings provided herein.

In addition, while the systems and methods are shown and describedherein as they could be used in conjunction with a semi-automatic jackdeployment system 16 that is operable to automatically deploy or extendthe various jacks 16 until the drill rig has achieved the desiredattitude, the systems and methods of the present invention could also beused with other types of jack deployment systems that are now known inthe art or that may be developed in the future. Still further, thesystems and methods of the present invention are not limited to use withhydraulically operated jack systems, and could be used on any type ofjack system, whether hydraulically powered, electrically powered, orsome other type of power source. Consequently, the present inventionshould not be regarded as limited to the particular vehicle types,applications, and environments shown and described herein.

With reference back now to FIGS. 1-3, one embodiment of the dynamic jackreference control system 10 is shown and described herein as it may beused on a blasthole drill rig 12 of the type commonly used in mining andquarrying operations to drill blastholes (not shown). Blasthole drillrig 12 may be comprise a retractable derrick 52 suitable for supportinga drill string 54 suitable for drilling or forming the blastholes. Drillrig 12 may be mounted on a pair of crawler tracks 56 that allow thedrill rig 12 to be moved or “trammed” from place-to-place to drill thevarious blastholes. In an embodiment where the drill rig 12 is to bemanned, drill rig 12 may also be provided with an operator cab 58 toallow a drill rig operator (not shown) to monitor and/or operate thevarious systems and devices of drill rig 12.

Drill rig 12 may also be provided with various other components andsystems, such as one or more power plants, electrical systems, hydraulicsystems, pneumatic systems, etc. (not shown), that may be required ordesired for the operation of the drill rig 12. However, because suchother components and systems that may comprise drill rig 12 arewell-known in the art, and because a detailed description of such othersystems and components is not required to understand or practice thesystems and methods of the present invention, the various othercomponents and systems of drill rig 12 that are not directly related tothe systems and methods of the present invention will not be describedin further detail herein.

Drill rig 12 is also provided with a plurality of jacks 14 that may beused to stabilize and/or lift drill rig 12 to the desired attitudebefore the drilling operation begins. In the embodiment shown anddescribed herein, the various jacks 14 are hydraulically powered and arecontrolled by the jack deployment system 16. Jack deployment system 16is operable to extend the various jacks 14 until they make initialcontact with the ground 60. Thereafter, jack deployment system 16 mayfurther extend the various jacks 14 to level the drill rig 12 orotherwise lift it to the desired attitude. Jack deployment system 16 mayalso retract the jacks 14.

Referring now primarily to FIG. 3, the various jacks 14 of drill rig 12are arranged in pairs. More specifically, a first pair of jacks 62 and64 are mounted to a first or “non-drill end” 66 of drill rig 12, whereasa second pair of jacks 68 and 70 are mounted to a second or “drill end”72 of drill rig 12. Each of the various jacks 14 may be controlled oroperated by a corresponding jack actuator 74. In an embodiment where thejacks 14 comprise hydraulic jacks, the various jack actuators 74 maycomprise hydraulic cylinders or “motors” that are used to extend andretract the jacks 14. Alternatively, in an embodiment having electricjacks 14, then the various jack actuators 74 may comprise electricmotors that may be operated to extend and retract the jacks 14. Stillother arrangements are possible, as would become apparent to personshaving ordinary skill in the art after having become familiar with theteachings provided herein. Consequently, the present invention shouldnot be regarded as to any particular type of jacks 14 (e.g., hydraulicor electric), nor to any particular type of jack actuator 74.

In the particular embodiment shown and described herein, the two“non-drill end” jacks 62 and 64 are controlled by a single hydraulicvalve and operate together, as functionally depicted in FIG. 3. That is,when operated by jack deployment system 16, both non-drill end jacks 62and 64 will extend or retract together. In contrast, the “drill end”jacks 68 and 70 are independently controlled. That is, the jackdeployment system 16 may extend and retract the drill end jacks 68 and70 independently of one another.

The jack deployment 16 controls the extension and retraction of thevarious jacks 14. Because the present invention involves varying theextension or retraction speed of the various jacks 14 depending on thetilt angle of the drill rig 12, the present invention comprises a speedcontroller 20 to allow the extension speeds of the jacks 14 to be variedin the manner described herein. In such a configuration, then, the jackdeployment system 16 is depicted in FIG. 3 as being operativelyassociated with speed controller 20. Stated another way, the primaryoperational control of the jacks 14 (e.g., the particular jacks 14 to beoperated, as well as whether they are to be extended or retracted) isprovided by the jack deployment system 16. The speed controller 20, asoperated by processor 18, controls or limits the extension or retractionspeed of the jacks 14 being controlled by jack deployment system 16.Further, because the system 10 may operate to control both the jackextension and retraction speeds, the term “extension” as used hereinshould also be regarded encompassing the term “retraction” depending onthe particular context in which the term is being used.

In an embodiment wherein the primary operational control of the jacks 14is provided by jack deployment system 16, the jack deployment system 16may also be connected to the pitch sensor 22 and the roll sensor 24 inthe manner illustrated in FIG. 3. The jack deployment system 16 uses therespective pitch and roll angles 26 and 30 sensed by the sensors 22 and24 to determine which of the jacks to operate (e.g., extend) to lift thedrill rig 12 to the desired tilt angle or set point attitude.

In accordance with the foregoing considerations, then, the jackdeployment system 16 may comprise any of a wide range of systems anddevices that are now known in the art or that may be developed in thefuture that are, or would be, suitable for controlling the various jacksin the manner described herein. Consequently, the present inventionshould not be regarded as limited to any particular type of jackdeployment system 16. However, by way of example, in one embodiment, thejack deployment system 16 may comprise a portion of a computerized drillcontrol system (not shown) that is operatively connected to the variousother systems and components associated with drill rig 12, including thehydraulic system that is used to extend and retract the jacks 14.

The processor 18 is used in the present invention to produce ordetermine the jack reference value. Processor 18 then applies the jackreference value to speed controller 20, which operates to control orvary the extension speeds of the jacks 14 being operated by jackdeployment system 16 in the manner already described. Accordingly,processor 18 may comprise a similar type of computer system and may beconfigured to communicate with jack deployment system 16 provided ondrill rig 12, either directly or via the speed control system 20, as maybe required or desired for any particular installation. Indeed, anddepending on the particular vehicle, the processor 18 may comprise aportion of the computerized control system used to operate the varioussystems and devices of the vehicle. Alternatively, of course, processor18 could comprise a separate system.

In any event, i.e., regardless of whether processor 18 comprises anindependent system or a portion of an existing computerized vehiclecontrol system, processor 18 is programmed to implement the methodsdescribed herein and to interface with the speed controller 20.Processor 18 also may be configured to interface with any other systemor device of drill rig 12, as may be required or desired in anyparticular application, as would become apparent to persons havingordinary skill in the art after having become familiar with theteachings provided herein.

Speed controller 20 may comprise any of a wide range of systems anddevices that are now known in the art or that may be developed in thefuture that are or would be suitable for controlling at least theextension speeds of the jacks 14 in the manner described herein. In anembodiment wherein the jacks 14 are hydraulically operated, speedcontroller 20 may comprise a variable hydraulic valve system capable ofvarying the flow rate and/or pressure provided to the varioushydraulically operated jack actuators 74. In an embodiment wherein thejacks 14 are electrically operated, speed controller 20 may comprise anelectric speed control system suitable for varying the voltage and/orcurrent provided to the various electrically operated jack actuators 74.However, because speed control systems for controlling or varying thespeed of various types of hydraulically- and electrically-operated jacksystems are well known in the art and could be readily provided bypersons having ordinary skill in the art after having become familiarwith the teachings provided herein, the particular speed controller 20that may be used will not be described in further detail herein.

Still referring to FIG. 3, processor 18 may also be operativelyconnected to the pitch sensor 22 and roll sensor 24. Pitch sensor 22 maybe mounted to any convenient location on drill rig 12 so that it sensesor detects the pitch angle 26 of drill rig 12. Pitch sensor 22 producesa pitch output signal 28 that is related to the pitch angle 26 of drillrig 12. See FIG. 1. In one embodiment, pitch sensor 22 senses the pitchangle 26 of drill rig 12 relative to horizontal, which is designated azero pitch angle. Pitch angles 26 toward the non-drill end 66 of drillrig 12 are assigned positive (+) pitch angles, whereas pitch anglestoward the drill end 72 of drill rig 12 are assigned negative (−) pitchangles, as designated in FIG. 1. Alternatively, the opposite signconvention could also be used. The pitch output signal 28 may beprovided in any convenient units, such as degrees or radians.Alternatively, the pitch output signal 28 could be dimensionless. By wayof example, in one embodiment, the pitch output signal 28 is provided toprocessor 18 in units of degrees.

Pitch sensor 22 may comprise any of a wide variety of pitch sensors thatare now known in the art or that may be developed in the future thatare, or would be, suitable for the intended application. Consequently,the present invention should not be regarded as limited to anyparticular pitch sensor. However, by way of example, in one embodiment,pitch sensor 22 comprises a single axis analog tilt sensor, part no.PN72162000-045, available from Measurement Specialties of Hampton, Va.(US) and sold under the trademark “ACCUSTAR® IP-66 Clinometer.”

Roll sensor 24 may be mounted to any convenient location on drill rig 12so that it senses or detects the roll angle 30 of drill rig 12. In amanner similar to the pitch sensor 22, roll sensor 24 produces a rolloutput signal 32 that is related to the roll angle 30 of drill rig 12,as best seen in FIG. 2. In the embodiment shown and described herein,roll sensor 24 senses the roll angle 30 of drill rig 12 relative tohorizontal, which is designated a zero roll angle. Roll angles 30 towarda non-cab side 76 of drill rig 12 are assigned positive (+) roll angles,whereas roll angles toward a cab side 78 of drill rig 12 are assignednegative (−) roll angles, as depicted in FIG. 2. Of course, the oppositesign convention could also be used. As was the case for the pitch outputsignal 28, the roll output signal 32 may be provided in any convenientunits, such as degrees or radians. Alternatively, the roll output signal32 could be dimensionless. By way of example, in one embodiment, theroll output signal 32 is provided to control system 20 in units ofdegrees.

Roll sensor 24 may comprise any of a wide variety of pitch sensors thatare now known in the art or that may be developed in the future thatare, or would be, suitable for the intended application. Consequently,the present invention should not be regarded as limited to anyparticular roll sensor. However, by way of example, in one embodiment,roll sensor 24 comprises a single axis analog tilt sensor, part no.PN72162000-045, available from Measurement Specialties of Hampton, Va.(US) and sold under the trademark “ACCUSTAR® IP-66 Clinometer.”

Finally, processor 18 may also be operatively connected to a memorysystem 46 for storing various types of data, program steps, andinstructions that may be implemented by processor 18. In certainembodiments, memory system 46 may also be used to store a look-up table(LUT) 44.

Before proceeding with the description, it should be noted that, as usedherein, the terms “tilt angle,” which in one embodiment also includesthe “pitch angle” and “roll angle,” may have slightly different meaningsdepending on the particular context. For example, when referring to thedata or information provided in the output signals from the sensors,such as the pitch output signal 28 from pitch sensor 22 and roll outputsignal 32 from roll sensor 24, these terms refer to the actual sensedangle(s) of the vehicle, whether in terms of degrees, radians, orwhether the terms are dimensionless. Stated simply, in this context, theterms tilt angle (e.g., specifically pitch angle and roll angle) referto the data produced by the tilt sensors, e.g., the pitch sensor 22and/or roll sensor 24, as the case may be.

However, when used in the context of determining the jack referencevalue, or whether the desired tilt angle has been achieved (e.g., asdetermined in step 38 of FIG. 4), then these terms refer to thedifference between the actual or sensed angle of the vehicle and thedesired set point value or attitude that is to be achieved by jackextension. In some cases, the values of these terms will be the sameregardless of context. However, in other cases, the values of the termswill differ depending on the context.

For example, in an embodiment wherein the pitch and roll angles aredeemed to be zero with respect to the horizontal, and when the desiredattitude or set point of the vehicle is to be the level condition (i.e.,aligned with the horizontal in both pitch and roll), then the absolutevalues of the tilt angle (e.g., the pitch angle 26 and roll angle 30)will be the same in both contexts. That is, if the pitch angle is +5 andthe desired pitch attitude or set point is the level condition (i.e.,0), then the pitch angle (or tilt angle) in the context of the pitchoutput signal 28 from pitch sensor 22 will be +5. Similarly, the pitchangle (or tilt angle) when used in the context of determining the jackreference value will also be 5. In contrast, if the desired pitchattitude or set point is not the level condition, or if the zeroreference in the pitch angle 26 (illustrated in FIG. 1), is not thehorizontal but some other angle, then the value of the pitch angle 26may differ in the two contexts.

However, because persons having ordinary skill in the art will readilyunderstand that the value of the tilt angles may vary depending on theparticular embodiment and context, and for convenience of description,the same terms “tilt angle” and/or “pitch angle” and “roll angle” willbe used in both contexts.

Referring now primarily to FIG. 4, the system 10 may implement a method34, i.e., via processor 18, for controlling the extension speeds of thejacks 14 provided on drill rig 12. A first step 36 of method 34 involvessensing the tilt angle, such as, for example, the pitch angle 26 androll angle 30 of drill rig 12. In this regard it should be noted that inmost applications, the processor 18 will sense both the pitch angle 26and the roll angle 30, because it will be desired to extend all of thejacks 14, thus affecting both the pitch and roll angles 26 and 30 of thedrill rig 12. However, it should be noted that in certain circumstancesit may only be necessary to sense the angle that is correlated with theparticular jack or jacks 14 that are to be extended. For example, in anembodiment wherein two jacks 14, such as non-drill end jacks 62 and 64,that are positioned on the same end (e.g., the non-drill end 66) ofdrill rig 12 and are also to be extended together, then it may bepossible to configure the system 10 so that processor 18 senses only thepitch angle 26, as the pitch angle 26 is strongly correlated with theextension of that pair of jacks 14. However, this is a limitedapplication and will not generally be undertaken in most situations.

Once processor 18 has sensed the pitch angle 26 and roll angle 30 ofdrill rig 12, processor 18 may store those angles in memory system 46for later access and processing, as will be described below. The nextstep 38 in process 34 may involve a determination of whether the desiredtilt angle (e.g., pitch and roll angles 26 and 30, as the case may be)has been achieved. If the desired tilt angle has been achieved, then thejack extension process may be terminated or stopped at step 40. If not,the process 34 continues to step 42.

Depending on the configuration of the particular embodiment, step 38 maybe conducted by processor 18 or by the jack deployment system 16. Forexample, in an embodiment wherein the jack deployment system 16exercises primary operational control of the jacks 14, step 38 may beperformed by jack deployment system 16, which may then terminate thejack extension process. Jack deployment system 16 could then send anappropriate signal to processor 18 so that processor 18 can ceaseimplementing method 34. Alternatively, in another embodiment, processstep 38 could be performed by processor 18 which could then provide anappropriate signal to jack deployment system 16 to terminate the jackextension process when the desired tilt angle has been achieved. Stillother arrangements are possible, as would become apparent to personshaving ordinary skill in the art after having become familiar with theteachings provided herein. Consequently, the present invention shouldnot be regarded as limited to any particular configuration ormethodology for determining when the desired tilt angle has beenachieved.

Continuing now with the description, the next step 42 in process 34involves the production of a jack reference value. As already mentioned,in one embodiment, the jack reference value refers to the percentage ofthe maximum jack extension (or retraction) speed available to theparticular jack or jacks that are being extended. Thus, a jack referencevalue of 100% means that the speed controller 20 will allow the jacks 14to extend at the maximum available rate for the particular jacksinvolved. Similarly, a jack reference value of 50% means that the speedcontroller 20 will limit the extension speed of the particular jack orjacks 14 being extended to one-half of the maximum available jackextension speed.

The jack reference value produced by processor 18 in step 42 is based onthe sensed tilt angle. Where two tilt angles are sensed, for example,the pitch angle 26 and the roll angle 30, then processor 18 will producea pitch jack reference value and a roll jack reference value. As will bedescribed in greater detail below, the pitch jack reference value may beused when extending those jack or jacks 14 that are highly correlated to(i.e., affect) the pitch angle 26 of drill rig 12. Similarly, the rolljack reference value may be used when extending those jack or jacks 14that primarily affect the roll angle 30 of drill rig 12. See alsoTable 1. By way of example, in the particular embodiment shown anddescribed herein, the pitch jack reference value will be used whenextending the two non-drill end jacks 62 and 64, as they are the primarymeans of changing the pitch angle of drill rig 12. On the other hand,the roll jack reference value will be used when extending either of thedrill end jacks 68 and 70, as they are the primary means for changingthe roll angle of drill rig 12.

Once the jack reference value or values (e.g., the pitch jack referencevalue and the roll jack reference value) have been produced at step 42,method 34 proceeds to step 48 wherein the jack reference value or valuesare applied to the speed controller 20. Speed controller 20 adjusts orvaries the extension speeds of the jacks 14 in accordance with the jackreference value at step 50. For example, if the pitch jack referencevalue is 100% and the roll jack reference value is 50%, the speedcontroller 20 will allow the non-drill end jacks 62 and 64 to beextended at the maximum available speed. However, when either of thedrill end jacks 68 and 70 are being extended (e.g., under the control ofjack deployment system 16), then speed controller 20 will limit theextension speed of the jacks to one-half of the maximum allowableextension speeds.

The processor 18 will continue to repeat the various steps of method 34until the drill rig 12 has achieved the desired tilt angle, asdetermined by step 38. That is, the processor 18 will continue to sensethe tilt angle, at step 36, produce a jack reference value or values (atstep 42, apply the newly-produced jack reference value or values to thespeed controller 20, and extend the jacks 14 until drill rig 12 hasachieved the desired tilt angle. Thereafter, the jack extension processcan be terminated, at step 40.

As already described, the jack reference value or values determined instep 42 are based on the sensed tilt angle, i.e., the sensed pitch angle26 and the sensed roll angle 30. In one embodiment, the jack referencevalue produced by step 42 is proportional to the sensed tilt angle, withhigher tilt angles resulting in higher jack reference values and lowertilt angles resulting in lower jack reference values. Depending on theparticular embodiment, the jack reference value may be selected to be adefined function of the sensed tilt angle. For example, in oneembodiment, the jack reference value may be linear function of thesensed angle, as depicted in FIG. 6. In another embodiment, the jackreference value may be an exponential function of the sensed tilt angle,as illustrated in FIG. 7. In still yet another alternative, the jackreference value may be determined by reference to a look-up table (LUT)44 (FIG. 3). In the example embodiment shown and described herein, thelook-up table (LUT) 44 may define jack reference value that is a stepfunction of the sensed tilt angle, as depicted in FIG. 9, although otherfunctions may be defined by the LUT 44. Various methods 80 and 81 thatmay be used to produce the jack reference values will now be describedin detail.

Referring now to FIGS. 5-7, processor 18 may implement method 80 toproduce a jack reference value that is a function of the sensed tiltangle. However, before proceeding with the description, it should benoted that, as used herein, the sensed tilt angle may be used to referto the sensed pitch angle 26, the sensed roll angle 30, takenindividually or together as the case may be and depending on theparticular jacks that are to be extended. As already described, in mostcases, the system 10 will sense both the pitch angle 26 and roll angle30 as both angles will be needed for the leveling process. However,other embodiments may utilize only one or the other of the pitch androll angles 26 and 30, depending on the particular circumstances and thejacks that are to be extended. However, in order to streamline thefollowing description, the term “tilt angle” should be regarded asincluding both the pitch angle 26 and the roll angle 30, takenindividually or together.

As also described above, and when used in this context, the term “tiltangle” refers to the difference between the actual tilt angle of thedrill rig 12 and the desired tilt angle, as opposed to the actual tiltangle of the vehicle. However, if the desired tilt angle is a levelvehicle and in a system wherein the pitch and roll angles 26 and 30 arezero when aligned with the horizontal, then the “tilt angle” used hereinwould coincide with the actual tilt angle of the drill rig 12, ignoringthe sign or polarity “+” or “−”) of the tilt angle.

A first step 82 in process 80 is to obtain the sensed tilt angle, eitherby retrieving it from memory system 46 or directly from the pitch and/orroll sensors 22 and 24. Thereafter, the tilt angle may be amplified (atstep 84) and scaled (at step 86) before arriving at the jack referencevalue, at step 88. Depending on the particulars of the amplification andscaling steps 84 and 86, the jack reference value may be made to be anyof a wide range of functions of the sensed tilt angle.

In one embodiment, the amplification and scaling functions may beembodied in appropriate software running on processor 18. However, inother embodiments, such amplification and scaling functions may beotherwise embodied, as would become apparent to persons having ordinaryskill in the art after having become familiar with the teachingsprovided herein. Consequently, the present invention should not beregarded as limited to any particular embodiment of the amplificationand scaling functions.

For example, and with reference now to FIG. 6, in one embodiment, thejack reference value may be a linear function 90 of the tilt angle. Inthis particular embodiment, the linear function 90 is such that a tiltangle of 0.1° will result in a jack reference value of about 10%,whereas a tilt angle of at least about 1 will result in a jack referencevalue of about 100%. Because the jack reference value is a linearfunction, a tilt angle of about 0.5° will result in a jack referencevalue of about 50%, as depicted in FIG. 6.

As is also depicted in FIG. 6, tilt angles (i.e., the difference betweenthe sensed tilt angle and the desired or set point tilt angle) in excessof about 1° will continue to result in a jack reference value of about100%. However, tilt angles of less than about 0.1° may result in a zeroreference value, as indicated by broken line 91, depending on thecharacteristics of the particular system and as described below.Alternatively, linear function 90 could be configured so that the jackreference value remains at 10% even if the tilt angle drops below 0.1°,as indicated by broken line 93.

Whether function 90 follows broken line 91, broken line 93, or someother relation, will depend on the particular characteristics of thejack deployment system 16. For example, in one embodiment, the jackdeployment system 16 could be configured to terminate the jack extensionprocess once the tilt angle of the drill rig 12 is within 0.1° of thedesired tilt angle. In such a configuration, it would not be necessaryto provide a jack reference value for tilt angles between 0° and 0.1°because the jack deployment system 16 would not operate the jacks 14within that range of tilt angles. However, in another embodiment, thejack deployment system 16 may continue to operate the jacks 14 eventhough the difference between the actual tilt angle and desired tiltangle falls below 0.1°. In this type of embodiment, then, it may bedesirable to configure linear function 90 to follow broken line 93,i.e., to provide a jack reference of 10%. This would allow the jackdeployment system 16 to continue to extend the jack 14 when thedifference is less than 0.1°.

In another embodiment, the amplification and scaling processes 84 and 86could be configured so that the jack reference value is an exponentialfunction 92 of the tilt angle. Referring now to FIG. 7, the exponentialfunction 92 is such that a tilt angle of 0.1° will result in a jackreference value of about 10%, whereas a tilt angle of at least about 1°will result in a jack reference value of about 100%. However, becausethe jack reference value is an exponential function of the tilt angle, atilt angle of about 0.5° will result in a jack reference value that isonly about 33%, as depicted in FIG. 7.

As was the case for the linear function 90, exponential function 92 maybe configured so that tilt angles in excess of about 1° will continue toresult in a jack reference value of about 100%. Tilt angles of less thanabout 0.1° may result in a zero reference value, as indicated by brokenline 95, or a 10% reference value, as indicated by broken line 97.Whether exponential function 92 follows broken line 95, broken line 97,or some other relation, will depend on the particular characteristics ofthe jack deployment system 16, as explained above for linear function90.

In another embodiment the jack reference value may be determined byreference to a look-up table (LUT) 44 provided in memory system 46. Inthis embodiment, processor 18 may implement method 81 to produce a jackreference value from the LUT 44. In a first step 83 in process 81,processor 18 retrieves or otherwise obtains the sensed tilt angle of thedrill rig 12. Processor 18 then accesses the LUT 44 in step 85 anddetermines the jack reference value that corresponds to the sensed tiltangle at step 87.

Look-up table 44 may define the jack reference value in any of a numberof ways. For example, and with reference now to FIG. 9, in oneembodiment, the LUT 44 defines a jack reference value that is a stepfunction of the sensed tilt angle. In the particular embodiment depictedin FIG. 9, the LUT 44 specifies a jack reference value of 25% for tiltangles ranging from about 0.05° to about 0.2°. LUT 44 specifies a jackreference value of 50% between tilt angles of about 0.2° to about 1°.Tilt angles greater than about 1° will return jack reference values of100%. Alternatively, LUT 44 may be programmed or established withalternate values or functions of the jack reference value, as wouldbecome apparent to persons having ordinary skill in the art.Consequently, the present invention should not be regarded as limited tolook-up tables 44 defining any particular relationship between the jackreference value and tilt angle. As mentioned, the particular jackreference value used to control the jack extension speed may varydepending on the particular jack that is to be extended as well as onthe particular tilt angle (e.g., pitch angle 26 or roll angle 30) thatis sensed. An example embodiment of a control schedule based on thelook-up table jack reference function depicted in FIG. 9 is illustratedin Table I:

TABLE I Jack Jack Reference Reference for for Non- Jack Reference SensedTilt Angle Cab-Side Cab Side for Non- Drill End (Pitch or Roll) Jack 68Jack 70 Jacks 62, 64 Roll < −1° 100% 0% 0% −1° < Roll < −0.2° 50% 0% 0%−0.2° < Roll < −0.05° 25% 0% 0% Roll > 1° 0% 100% 0% 0.2° < Roll < 1° 0%50% 0% 0.05° < Roll < 0.2° 0% 25% 0% Pitch > 1° 0% 0% 100% 0.2° < Pitch< 1° 0% 0% 50% 0.05° < Pitch < 0.2° 0% 0% 25% Pitch < −1° 100% 100% 0%−1° < Pitch < −0.2° 50% 50% 0% −0.2° < Pitch < −0.05° 25% 25% 0%

The dynamic jack reference control system 10 may be utilized as followsto extend the various jacks 14 to level the drill rig 12 or otherwiseraise it to the desired attitude. Assuming that the various jacks 14have been extended to the point where they have made firm groundcontact, the jack deployment system may be activated to extend thevarious jacks 14 until the drill rig has achieved the desired set point.In this example, the desired set point will be a level condition,although other attitudes may also be desired. In addition, the jackdeployment system will already be configured or programmed to extend thevarious jacks in accordance with the control schedule and jack referencevalues set forth in Table I. In this example, the jack deployment system16 is operatively associated with the pitch and roll sensors 22 and 24and will have already determined the initial attitude of drill rig 12.In addition, however, processor 18 will also be activated to determinethe various jack reference values to be applied to speed controller 20.

If the initial tilt angles (e.g., either the pitch angle 26 or rollangle 30) exceed about 1°, the processor 18 produces jack referencevalues of 100%. These jack reference values are applied to theparticular jack 14 or jacks 14 to be extended to achieve the levelcondition. For example, and with reference to FIG. 1 and Table I, if thedrill rig 12 is initially pitched toward the non-drill end 66 by morethan about 1° (i.e., a pitch angle greater than about +1), then thesystem 10 will apply a 100% jack reference to both non-drill end jacks62 and 64 as they are being extended. This jack reference of 100% willcontinue to be applied until the pitch angle decreases to less thanabout 1°, at which point the system 10 will reduce the jack reference to50% in this example. The 50% jack reference value will be applied untilthe pitch angle decreases to less than about 0.2°, at which point thesystem 10 will further reduce the jack reference to 25%. This jackreference of 25% will continue to be applied until the pitch angledecreases below about 0.05 or until the system determines that thedesired pitch angle has been achieved (i.e., in step 38 of FIG. 4). Byway of example, in this particular embodiment, the jack extensionprocess will be terminated when the sensed pitch angle falls below about0.1% at which point the drill rig 12 is substantially level with respectto pitch.

Similar control schedules may be applied to the other jacks (i.e., thedrill end jacks 68 and 70) to achieve the desired roll angle or setpoint and/or to correct negative pitch angles (i.e., when the drill rig12 is pitched toward the drill end 72). For example, if the drill rig 12is pitched toward the drill end 72, i.e., at a negative (−) pitch angle,both drill end jacks 68 and 70 may be extended together to raise orelevate the drill end 72, thus leveling the drill rig 12 with respect topitch. In addition, either one of the drill end jacks 68 or 70 may beextended as required to level the drill rig 12 with respect to roll, orto otherwise achieve a desired roll angle.

For example, if the drill rig 12 is initially tilted toward the non-cabside 76 (FIG. 2), i.e., if the drill rig 12 exhibits a positive (+) rollangle 30, then the system will extend the non-cab side jack 70 until thesensed roll angle falls below about 0.1° in this example. As the non-cabside jack 70 is being extended, the system 10 will apply the variousreference values listed in Table 1. That is, the system will apply ajack reference value of 100% to the jack 70 if the roll angle exceedsabout +1°. The system will decrease the jack reference value to 50% whenthe roll angle 30 falls below about 1° and will further decrease thejack reference value to 25% when the roll angle falls below about 0.2°.In this example embodiment, the system will terminate extension of thenon-cab side jack 70 when the sensed roll angle falls below about 0.1°.Alternatively, of course, a similar control schedule may be applied tothe cab side jack 68 to correct negative roll angles 30.

Having herein set forth preferred embodiments of the present invention,it is anticipated that suitable modifications can be made thereto whichwill nonetheless remain within the scope of the invention. The inventionshall therefore only be construed in accordance with the followingclaims:

What is claimed is:
 1. A control system for extending at least one jackon a vehicle, comprising: a tilt sensor, the tilt sensor beingconfigured to sense a tilt angle of the vehicle; a jack deploymentsystem connected to the tilt sensor, the jack deployment system beingconfigured to extend the at least one jack; a speed controlleroperatively associated with the jack deployment system and the at leastone jack; and a processor operatively associated with the tilt sensorand speed controller, the processor being configured to: evaluate thesensed tilt angle against a desired tilt angle of the vehicle todetermine if the desired tilt angle has been achieved, produce a jackreference value using a difference between the sensed tilt angle and thedesired tilt angle, if the desired tilt angle has not been achieved, andapply the jack reference value to the speed controller, the speedcontroller being configured to control a speed of jack extension for theat least one jack relative to the jack reference value, the jackreference value being a percentage of maximum jack extension speedavailable for the at least one jack.
 2. The control system of claim 1,further comprising a jack actuator and wherein the speed controllercomprises an actuator control system operatively associated with thejack actuator.
 3. The control system of claim 2, wherein the jackactuator comprises a hydraulic jack actuator and the actuator controlsystem comprises a hydraulic valve system.
 4. The control system ofclaim 1, further comprising a memory system operatively connected to theprocessor and configured to store a look-up table of jack referencevalues corresponding to sensed tilt angles.
 5. The control system ofclaim 4, wherein the processor is configured to produce the jackreference value by selecting from the look-up table: a jack referencevalue of about 25% when the sensed tilt angle is in a range from about0.05° to about 0.2°; a jack reference value of about 50% when the sensedtilt angle is in a range from about 0.2° to about 1°; and a jackreference value of about 100% when the sensed tilt angle exceeds about1°.
 6. The control system of claim 4, wherein the memory system isconfigured to store program steps for implementation by the processor.7. The control system of claim 1, wherein the processor comprises: anamplifier configured to produce an amplified tilt angle by amplifyingthe sensed tilt angle; and a scaler configured to scale the amplifiedtilt angle to produce the jack reference value.
 8. The control system ofclaim 1, wherein: the tilt sensor comprises a pitch sensor configured tosense a pitch angle of the vehicle, and a roll sensor configured tosense a roll angle of the vehicle; the jack reference value comprises apitch jack reference value and a roll jack reference value, the pitchjack reference value being a percentage of maximum extension speedavailable for a jack correlated to the pitch angle of the vehicle, andthe roll jack reference value being a percentage of maximum extensionspeed available for a jack correlated to the roll angle of the vehicle;the processor is configured to: evaluate the sensed pitch angle againsta desired pitch angle of the vehicle to determine if the desired pitchangle has been achieved, evaluate the sensed roll angle against adesired roll angle of the vehicle to determine if the desired roll anglehas been achieved, produce the pitch jack reference value using thesensed pitch angle if the desired pitch angle is not achieved, producethe roll jack reference value using the sensed roll angle if the desiredroll angle is not achieved, and apply the pitch jack reference value andthe roll jack reference value to the speed controller; and the speedcontroller is configured to control the speed of jack extension for thejack correlated to the pitch angle relative to the pitch jack referencevalue and control the speed of jack extension for the jack correlated tothe roll angle relative to the roll jack reference value.
 9. The controlsystem of claim 1, wherein the jack reference value is proportional tothe sensed tilt angle.
 10. The control system of claim 9, wherein thejack reference value is a linear function of the sensed tilt angle. 11.The control system of claim 9, wherein the jack reference value is anexponential function of the sensed tilt angle.
 12. The control system ofclaim 1, wherein the speed controller is configured to control a speedof jack retraction for the at least one jack relative to the jackreference value, the jack reference value being a percentage of maximumjack retraction speed available for the at least one jack.
 13. A controlsystem for extending and retracting at least a first jack and a secondjack on a vehicle, comprising: a tilt sensor, the tilt sensor beingconfigured to sense a first tilt angle of the vehicle for the first jackand a second tilt angle for the second jack; a jack deployment systemconnected to the tilt sensor, the jack deployment system beingconfigured to extend the first jack and the second jack; a speedcontroller operatively associated with the jack deployment system andthe first jack and the second jack; and a processor operativelyassociated with the tilt sensor and speed controller, the processorbeing configured to: produce a first jack reference value using thefirst sensed tilt angle and produce a second jack reference value usingthe second sensed tilt angle, apply the first jack reference value tothe speed controller, the speed controller being configured to control aspeed of jack extension and retraction for the first jack relative tothe first jack reference value, the first jack reference value being apercentage of maximum jack extension and retraction speed available forthe first jack, and apply the second jack reference value to the speedcontroller, the speed controller being configured to control a speed ofjack extension and retraction for the second jack relative to the secondjack reference value, the second jack reference value being a percentageof maximum jack extension and retraction speed available for the secondjack.
 14. The control system of claim 13, wherein the first jackreference value and the second jack reference value are differentpercentage values.
 15. The control system of claim 13, wherein theprocessor comprises: an amplifier configured to produce first and secondamplified tilt angles by amplifying the first and second sensed tiltangles; and a scaler configured to scale the first and second amplifiedtilt angles to produce the first and second jack reference values.